Hydraulic power transmitter



Jim 1940- H. SINCLAIR ET AL 2,187,667

HYDRAULI C POWER TRANSMITTER Filed April 4, 1938 7 Sheets-Sheet 1 2 40 r{82 ?3 4/ I7 -13 l 42 16 I4 I 23 60 I 33 F 22 I 32 2 72 19 20 2 S g ML MM"M 1940- H. SINCLAIR El AL 2,187,567

HYDRAULIC POWER TRANSMITTER Filed Apiil 4, 1958 7 Sheets-Sheet 2 a. V v

Jan. 16, 1940- H. SINCLAIR ET AL HYDRAULIC POWER TRANSMITTER Filed April 4, 1938 7 Sheets-Sheet 3 H. SINCLAIR Er AL 2,187,667 HYDRAULIC POWER TRANSMITTER Filed April 4, 1958 7 Sheets-Sheet 4 ii /Q 1940- H. SINCLAIR El AL HYDRAULIC POWER TRANSMITTER Filed April 4, 1938 7 Sheets- Sheet s y "in JZy.

J v M Jan. 16, 1940.

H.- SINCLAIR El AL HYDRAULIC POWER TRANSMITTER Filed Apfil 4, 1958 ll-I llll I A- m OO Patented Jan. 16, 1940 UNITED STATES PATENT OFFICE HYDRAULIC POWER TRANSMITTER Application April 4, 1938, Serial No. 199,901 In Great Britain April 8, 1937 19 Claims.

The present invention relates to hydraulic power transmitters of the kinetic type and provided with scooping means whereby the liquid content of the working chamber thereof can be varied while the transmitter is operating, as disclosed in the specification of Patent No. 1,859,607.

An object of the present invention is to provide an improved scoop-controlled hydraulic power transmitter requiring only a relatively small quantity of working liquid, which is continuously cooled while power is being transmitted.

A further object is to provide such a device which is simple in design and easy to control, and which is adapted for use in confined spaces.

Another object is to provide a hydraulic power transmitter which is adapted for use as an automatic starting clutch for electric motors, and engines, which do not conveniently develop a high starting torque.

According to this invention in one aspect the improved hydraulic power transmitter comprises a working chamber including driving and driven vaned elements, a reservoir chamber arranged to rotate with said working chamber, a drain port which is incapable of being closed while said chambers are rotating, which communicates between said chambers and which is capable of exhausting working liquid, under the influence of its energy of motion, from said working chamber, a scoop which is disposed in said reservoir chamber and which is capable of angular displacement eccentrically with respect to the axis of rotation of the transmitter, a filling duct leading from said scoop to said working chamber, and means for controlling the displacement of said scoop.

According to this invention in another aspect, a hydraulic power transmitter of the kinetic type comprises a working chamber including driving and driven vaned elements, a reservoir.

chamber arranged to rotate with said working chamber and having an efiective capacity of at least 50 per cent of the normal maximum liquid content of the working chamber, apermanently open passage between said chambers, which is adapted to exhaust at least a part of the liquid content of said working chamber, when said chambers are at rest, a scoop disposed in said reservoir chamber for engaging liquid therein; and a filling duct at all times communicating between said scoop and said working chamber, said scoop being arranged to effect a limited rate of filling such that the transmitter is enabled to operate as a starting clutch.

The features of the invention will be explained with reference to the examples shown in the accompanying drawings in which- Fig. l is a sectional side elevation of one form of hydraulic coupling in accordance with this 5 Fig. 6 shows diagrammatically in section another modification especially suitable for use as an automatic starting clutch for an electric motor,

Fig. 7 is an end elevation partly in section, to a smaller scale, of the arrangement shown in Fig. 6,

Figs. 8 and 9 show in section respectively two further modifications which are especially suitable ior marine installations, and

Fig. 10 shows a modified part adapted for substitution in the coupling shown in Fig. 6.

Referring to Figs. 1 and 2, a vaned impeller element includes a dished shell ll] having a boss ll fixed to a driving shaft [2, which may be the shaft of a synchronous electric motor. A dished shell l4 encloses the back of a vaned runner ele- 3o ment 15 with as small a clearance as possible and its outer edge is clamped by screws l6 between a flange l3 on the impeller and a ring ll,

the impeller shell It!v and the shell H co-operating to form a working chamber. A hollow run- 5 ner'shaft l8, to which the runner I5 is fixed, passes with a small radial clearance through a thick manifold sleeve l9 which is kept stationary by a supporting bracket 20. The dished shell [4.

has a central aperture 2i accommodating the inner end of thissleeve. The inner end of the runner shaft is supported in the boss ll of the impeller by a self-aligning journal bearing 22. Axial spacing of the impeller and runner is maintained by a rod 23 passing with radial clearance through and fixed at its outer end 24 to the hollow runner shaft. The inner end of the rod 23 is fixed by an adapter 25 to the inner race of a bi-directional thrust bearing 25 the outer race of which is clamped to the huh I I by a screwed'plug 21. A drivenshaft 30 is supported in bearings not shown, and to it is fixed a flange 3| accommodating a plurality of compressed rubber bushes 32 the inner steel sleeves 33 of which are engaged with pins 34 fixed in a flange 35 on the runner shaft.

The shell I 4 is enclosed in turn by a pressed and rolled steel casing having a substantially 5 cylindrical portion 40, welded at one end to the ring I 1, and an end wall portion 4| in which is a central aperture 18 accommodating the sleeve Hi. The casing 40, 4| and theshell |4 form a reservoir chamber rotating with the impeller and m communicating with the working chamber by a plurality of permanently open small drain ports 42 formed in the shell H at or almost at the radially-outermost part of the working chamber and uniformly distributed about the coupling 15 axis. In this example the effective capacity of the reservoir, namely the volume of the annular portion of this reservoir, between the casing por tion 40 and a cylindrical surface which is coaxial with the shafts and which is at a radius equal to the distance from the shaft axis to the drain ports 42, is not less than the normal maximum liquid content of the working chamber. By normal maximum liquid content is meant the smallest quantity of liquid contained in the 25 working chamber that yields minimum slip between thev impeller and the runner when power is being transmitted. This quantity may be less than the volume of the working chamber as a whole..

30 A scoop in the form of a tube 43 is fixed to a boss 44 which in turn is fixed to a pin 45 which is journalled in the fixed sleeve I9 so as to be capable of angular displacement about an axis 46 parallel to the axis of rotation of the cougg pling. A control lever 41 is keyed to the pin 45 and is provided with a latch 48 (Fig. 2) cooperating with a fixed notched quadrant 49. The lever can be displaced between positions A and .B and latched in thesepositions as well as 40 in several intermediate positions. An arcuate guide 50 is fixed to the lever 41, and a flexible wire 52 is fixed to a lug formed at one end of the guide 50, the wire passing over a fixed' pulley 53 and supporting" a weight 54 which 5 therefore urges the lever 41 clockwise, as seen in Fig. 2, with a uniform torque.

The scoop tube boss 44 (Fig. l) is accommodated in a transverse groove 55 formed in the manifold sleeve l9, and this boss is provided with 50 a port 56 which communicates with the bore of the scoop tube and which is so shaped that,

in all positions of the scoop tube it is open to a port 51 formed in the inner face of the groove 55. When the hydraulic coupling is a large 55 one, or intended to work for long periods at high torque and slip, the port 51 communicates by a duct 58 with a flanged union 6| (Fig. 2)

forming a fiow connection to an external cooler (not shown). A flanged union 62, forming the 50 return connection to the cooler, communicates by a duct 59 with a port 60 (Fig. l) in the inner end of the sleeve. The port 60 leads to an annular groove-63 in the runner from which lead a plurality of filling ducts 64 for charging the 55 working circuit. Where the coupling is small or employed for light work, the external cooler and the ducts 58 and 59 maybe-omitted, the port 51 leading directly to the port 60. a

The runner shaft I8 is provided with thrower 7o rings arranged to throw working liquid, which leaks between the sleeve l9 and this shaft, into a ring groove 1| from which it drains by a duct 12 tothe reservoir chamber.

The central aperture 18 in the end wall 4| 01' the reservoir chamber is sealed with respect to the sleeve l9 by a labyrinth gland which includes a cylindrical'tube 13 fixed to the wall 4| and having fixed between its ends an annular diaphragm 14 the aperture of which is slightly larger in diameter than the adjacent part of the 5 sleeve 9. Drain ports 15 are provided in the marginal portion of this diaphragm. An annular disk 16, having a diameter slightly less than the internal diameter of the tube 13, is fixed to the sleeve l9 and disposed close to the diaphragm 1 14 and on the side thereof remote from the end wall 4|. The outer surface of the sleeve l9 between the end wall 4| and the diaphragm 14 is provided with circumferential grooves 11 which serve to'throw off working liquid which tends to 15 creep along this surface towards the aperture 18.

The end wall 4| of the reservoir chamber is slightly bulged to render it stiff, and to it is secured an accurately turned and faced ring 80 juxtaposed to and having the same diameter as a similarly machined annular facing 8| on the bracket 20. The members 80 and 8| cooperate to form a means for checking, by feeler gauges and a straight edge, the alignment and the axial relationship of the fixed sleeve I9 and the driving parts of the coupling. I

The peripheral wall 40 of the reservoir is provided with a circumferential outward bulge in the form of a groove 82 adapted to receive the lip of the scoop tube 43 when it is in one extreme position.

The apparatus operates as follows. A measured quantity of working liquid is admitted through a filling plug 83 and drains to the lower part of the reservoir chamber (the axis of .rotation being horizontal), some of it entering the working chamber by those of the drain ports 42 that are near the bottom. The control lever is latched in position A so that the scoop tube is fixed in position a, its lip being at the maximum distance from the reservoir wall 40. The driving shaft is now set in rotation in the direction of the arrow in Fig. 2, and owing to centrifugal force any liquid that may be in the working chamber is discharged into the reservoir cham- 4,5 ber by the drain ports 42, and the liquid in the reservoir chamber forms a ring the inner cylindrical surface of which is denoted by 84. The radius of the surface 84 is slightly larger than the distance of the lip of the scoop tube from the coupling axis, so that the scoop tube is inoperative and the working chamber remains empty.

If the control lever 41 is now moved to and latched in a position between the positions A and B, the scoop tube is displaced oppositely to the direction of rotation of the chambers so as to cause its lip to be submerged in the ring of liquid in the reservoir. As this liquid is moving in the direction opposite to that in which the 0 mouth of the scoop is facing, liquid is picked up by the scoop and caused to flow through the port into the working chamber, the rate of transfer being rapid until the diameter of the inner surface of the liquid ring in the reservoir chamber has expanded so far that it tends to leave the lip of the scoop. A restricted discharge of liquid drains from the working chamber through the drain ports'42, being balanced by a similar flow returned to the working chamber by the scoop tube, so that the liquid content of the working chamber is kept constant at a predetermined value corresponding to the position of the control lever.

If the control lever is now moved to and 15 latched in position B, the scoop tube assumes position b in which its lip enters the groove 82 and the reservoir chamber is thereby substantially emptied, the ring of liquid flowing axially into the groove 82 as its thickness approaches zero. The liquid content of the working chamber is now maintained at its normal maximum value.

As long as liquid is being circulated through the working chamber, it is subjected to cooling in various ways. Firstly, the jets of heated liquid discharged by the drain ports 42 are directed on to the wall 40 of the reservoir, which is exposed to the atmosphere, and the consequent rapid fiow over this wall causes heat to be abstracted from the liquid. Secondly, the scoop tube agi tates the liquid in the reservoir and assists in cooling it by causing it to scour the wall 40. Thirdly, since the back of the impeller I is unshrouded, and since the vortex circulation in the working chamber causes the liquid therein to fiow rapidly over the impeller vanes and shell,

heat is thereby abstracted from the liquid by the.

impeller and transferred to the air in which the back of the impeller is exposed.

If desired, a by-pass orifice 85 may be formed in thescoop tube and so positioned as to direct a Jet of liquid on the radially inner part of the end wall ll of the reservoir chamber, which is not normally wetted, so that this wall also assists in cooling.

If, when the driving shaft is rotating, the scoop tube is returned to position a, the working chamber empties into the reservoir chamber through the drain ports 42. I1 now the driving shaft is retarded to a very low speed, the ring of liquid in the reservoir chamber collapses, and

under these circumstances the extension of the gland tube I3 to the right of the disk 16 has an important effect in preventing splashing of liquid through the gland. The dimensions 01' the reservoir chamber are such that the ,whole of this liquid can be accommodated in the reservoir chamber below the level oi the lowest part of the aperture 18 in the wall I. As soon as the driving shaft has come to rest, the-liquid level falls somewhat, since some of the liquid flows back into the working chamber through those of the ports I! that are near the bottom.

The outward bulging of the peripheral wall of the reservoir chamber in way of the scoop tube is important where a compact construction is desired. 11' a plain cylindrical wall is used, the scoop is unable to take up the outermost part of the ring of liquid in the reservoir, which serves no useful purpose and which has a considerable volume owing to its large diameter. This additional volume of useless liquid has to be accommodated below gland level when the coupling is at rest, so that the diameter or the reservoir has to be increased.

In place of the groove 82 shown in Figs. 1 and 2 which is deep enough to accommodate the whole mouth of the scoop tube, there may be employed a shallow groove (such as is shown in Fig. 6) which accommodates only the lip portion at the radially outermost edge oi the mouth.

when the coupling is operating, the torque imposed on the control pin 45, due to the pressure of the ring of liquid in the reservoir chamber on the scoop tube, attains its maximum value when the whole of the liquid content of the coupling is in the reservoir chamber and the-scoop is in position b. The counterweight M is just heavy enough to overcome this maximum torque.

The modification shown in Fig. 3 is designed to secure a small over-all diameter and employs draining means for the working circuit operating asv described in the specification of Patent No. 1,937,364,

The working chamber is formed by a shell Ila, fixed to the driving flange Ma, and the impeller Ilia. The runner I50 which is fixed to the runner shaft l8a, is placed between the'impeller and the driving shaft. The peripheral portions of the impeller and the shell [4a are rigidly clamped together in a ring Ila by means of a hollow screw-threaded plug 90 engaged in this ring.

The impeller is provided with a core guide member 9| which includes a channel 92 opening towards the coupling axis opposite the gap 94 between the vaned elements at the return junc..- tion of the working circuit. Ducts 93 lead from the channel 92 through the impeller to drain ports 42a, which are directed towards the peripheral wall 40a of the reservoir chamber. This wall is welded to the ring Ha andis bulged outwards at 82a in way of the scoop tube 43a, for the reason hereinbeiore described. The scoop tube is fixed to a pin 45a journalled in'a boss 98 on the fixed sleeve Illa. A gear wheel 99, also fixed to the scoop tube, engages with gear teeth I00 formed in the end of a control sleeve Hil journalled in the fixed sleeve Na and capable of being rocked by a control lever 41a to displace the scoop tube. Liquid picked up by the scoop tube is delivered through a duct 95 to filling passages 96 passing through the boss of the impeller.

So long as there is any appreciable quantity of liquid in the working chamber and the coupling is transmitting torque, part of the vortex ring of liquid enters the channel 92 through the gap 94 and is discharged by the drain ports 42a. The effective capacity of the reservoir in this example is equal to the volume of the normal maximum liquid content of the working chamher, that is to say, this volume can be accommodated in the reservoir between the peripheral surface 40a. and a cylindrical surface co-axial with the coupling and having a radius not less than the radial distance from the coupling axis to the overflow lip 92a of the channel 92.

with the arrangement shown in Fig. 3 it is desirable to keep the diameter of the aperture 18 in the end wall of the reservoir as small as possible, so as to enable the rest level of the liquid in the reservoir to be kept below this aperture without an excessive length of reservoir.

Figs. 4 and .show an arrangement in general similar to that described with reference to Figs. 1 and 2, but provided with the hydraulicallyactuated rapid-emptying'valves disclosed in the specification of British Patent 470,056. These valves keep closed so long as a supply of liquid is maintained to their control ducts, and they open automatically when this supply ceases. When the hydraulic coupling is transmitting heavy torque, the vortex circulation causes substantial back pressure in the duct connecting the scoop tube to the working chamber: consequently, it this duct were arranged to feed the control duct or rapid-emptying valves as well as the working chamber, back flow from the working chamber would hold these valves closed when the scoop tube was first withdrawn from the liquid in the reservoir and when the torque load was high.

Where it is desired to avoid this eiIect, the control liquid for the valves is supplied. separately from the liquid for charging the working charm u bcr, and in the arrangement shown in Figs. d and 5 an auxiliary scoop tube Hll is employed to supply the valves. The shell Mb that covers the back of the runner is provided with a plurality of rapid-emptying valves uniformly spaced round its periphery. One of these is shown at iii. A port H2 leading from the working chainher is surrounded by an annular port i it leading to duct lit opening into the reservoir. lThe permanently open drain ports 3% for the worlo lug chamber open to the duct 8 it. A thin valve disk l i5 is adapted to close the ports 5 l2 and il -3 under the influence oi fluid pressure exerted by a column of liquid in the control duct ll'l formed in the shell Mb and leading from a collecting channel till to a passage through a plug ill: which closes the valve chamber. small port H9 in this plug leads from the valve chamber tothe reservoir. The auxiliary scoop tube till is fixed to the main scoop tube, and its inner end till is arranged to discharge into the collecting channel lid, while its lip extends, with reference to the coupling axis, slightly beyond the lip oi the main scoop tube, the circumferential bulge 82b, in the reservoir wall coo being suitably shaped to accommodate the two lips.

When the coupling is operating with a fixed liquid content, both scoop tubes piclr up liquid. The main scoop tube 63 delivers through a duct see to the working chamber a flow replacing the discharge through the drain ports 32th. The auriillary scoop tube ti l delivers to the channel lit a flow slightly exceeding the discharge through the valve ports lid, so that the control ducts ill are maintained full of liquid and the valve disks H5 seal the ports M2 and lit.

If the control lever ll is now operated to withdraw both scoop tubes from the liquid in the reservoir, the control ducts i ll drain through the ports Md, and the consequent fall in pressure in the valve chambers all ws the valve disks to be moved outwards by th pressure acting in the ports H2 due to the liquid in the working chamber. The ports H2 and Mil are now put into communication with each other through the valve chamber, and the working chamber can empty rapidly.

In order to refill the working chamber, the scoop is moved slowly so as to submerge the lip of only the auxiliary tube I Ill, so that the valve control ducts are recharged with liquid and the valve disks thereby returned to their seatings against the ports M2 and H3. On further movement of the control lever the lip of the main scoop tube is submerged, and liquid is delivered to the working chamber.

When the coupling is operating under high H torque, some liquid is forced, by the action of the vortex circulation, out of the working chamber through the annular space between the shell bib and the fixed sleeve it. In order to prevent this leakage from entering the channel lit, a shield tube 522 is red in the central aperture of the shell l lb and projects beyond the lip of the channel llll.

Figs. 6 and 7 show a coupling similar in general to that shown in Fig. 1, but adapted for use as an automatic starting clutch for a three-phase electric motor ltd. The impeller l o is fixed to the driving flange l2c of the motor. The scoop tube control pin 45 is fixed to a crank arm 410 which is movable between stops l3! and Rita and which is urged in aclockwise direction (Fig. '7) by a tension spring I33 acting through a link I32 and pivotally mounted on a'bolt l3 adjustably securedto the bracket 20c. The spring I33 biases the scoop tube in such a direction that it tend: tobe displaced towards the position (shown in full lines in Fig. 7) yielding the minimum degree of filling of the working chamber and at the same time to move oppositely to the direction of rotation of the working and reservoir chambers (shown by the arrow). The torque imposed on the scoop tube by the spring it; is high enough to keep the crank arm ile against the stop idle and therefore the scoop tube in the position shown in full lines in 7, while the motor 5% is accelerating on star connection, where a star-delta starter is used, or on low voltage where a tapped transformer starter used, the mouth of the scoop tube being only partly submerged below the s me surface 5 20 under these conditions and the rate of filling oi the working chamber being relatively slow owing to both the incomplete immersion of the mouth and the reduced radius at which it acts. Since the torque-transmission capacity or? coupling is thus kept very low, the motor accelerates freely, and as its speed approaches synchronisrn and the starter is switched to delta (or to full voltage) the torque on the scoop tube due to the scooping action overcomes the biasing torque and the tube swings automatically to the position shown in dotted lines. Its mouth is now fully submerged and is at the maximum radius from the coupling axis. The working circuit is therefore rapidly filled. If desired, one or more vanes E35 (Fig. 6) may be fitted to the scoop tube at or near its mouth.

The arrangement shown in Fig. 5 may be modifiecl by omitting the biasing means, the movable Scoop and its supporting sleeve and substituting the sleeve lQd and fixed scoop Md shown in Fig. 10. The mouth of this scoop is adjacent to the peripheral wall or" the reservoir chamberfbut its area is restricted to such an extent that the motor can be run up to speed before the coupling is filled enough to make its torque transmission capacity so high as to cause the motor to take excessive current.

The effective reservoir capacity of the improved hydraulic coupling when used as starting clutches for electric motors may be less than the volume of the normal maximum'liquid content of the working chamber, but should not be less than 50 per cent. of this volume.

In arrangements such as those shown in Figs. 6 and 10 the peripheral leak-off ports 42 may be omitted and the clearance space 42a. between the shell M and the fixed sleeve is relied on for partly exhausting the working chamber to the reservoir chamber when the motor is at rest.

Fig. 8 shows a coupling suitable for use, for example for connecting one of a plurality of marine engines to a common propeller shaft. The shell Me, the impeller llleand the reservoir casing 88c rotate with the driving flange I2e, while the runner 15s is fixed to a driving shaft we of transmission gearing (not shown). The scoop tube 63, is plvotally mounted in the fixed mani- -fold sleeve tile and operable for engaging and disengaging the coupling while the engine connected to the flange l2e is running. The scoop feeds a duct 58c leading to a cooler M0, the return ducts 59c from thecooler terminating in a filling and intercepting port MI in the upper surface of the sleeve I92. Bores, such as I42, lead from each of the passages of the impeller we to the interior of the impeller boss and register,

when in the uppermost position, with the port I. A shallow annular bailie I43 projects into the circuit from the boss of the impeller at its inlet edge. The normal circulation of working liquid follows the full-line arrows. A reversible pump I44, which is drowned or otherwise arranged to be self-priming, is provided in parallel with the cooler I40, and this cooler may be provided with a stop valve I45. The drain ports 42 of the working chamber are fitted with needle valves I46 by which they can be closed when the driving parts are stationary.

If it is desired to disconnect the engine which drives the flange. I2e from theshaft I8e, this engine being stationary, the needle valves I46 are shut, and, when the shaft We is set in rotation by another engine, the pump I44 is run in such a direction as to cause a circulation following the dotted arrows. Liquid in the coupling is circulated by the runner and the part that enters the uppermost passages of the impeller is trapped by the baffle I43 and drains through the upper bores I42 to the intercepting port I4! whence it is discharged by the pump I44 to the reservoir chamber. When the working chamber has been completely emptied, the pump is stopped.

To enable the driving shaft to be set in rotation by power derived from the shaft 18c, the needle valves I46 are opened and the pump I44 is driven in the opposite direction so as to draw liquid from the reservoir chamber through the scoop tube, which is set in its lowest position, and deliver it to the working chamber. The valve I45, if provided, may be shut while the pump is operating to prevent short-circuiting of some of the flow through the cooler.

The coupling shown in Fig. 9 is arranged similarly to that in Fig. 8, except that the impeller ID is fixed directly to the driving shaft. When the driving parts are stationary and the driven shaft is running, the runner I5f raises liquid in the working circuit and discharges some of the liquid which it raises against the inner side of the now stationary shell I41. The part of this discharge that trickles down from the uppermost portion of this shell is intercepted by the port I41 and withdrawn by the pump.

In the kind of couplings shown in Figs. 1, 4, 6, 8, and 9, where the working chamber has peripheral drain ports and where the effective capacity of the reservoir is required to equal the volume of the normal maximum liquid content of the working chamber, it is convenient to make the inside diameter of the reservoir (excluding the groove or other bulge) between 125 and 140 per cent. of the outer profile diameter (indicated by D in Fig. 1) of the toroidal working circuit 01' the coupling.

For certain purposes, however, where complete interruption of the transmission of power through the hydraulic transmitter is unnecessary, the effective capacity of the reservoir chamber may be less than the volume of the normal maximum liquid content of the working chamber.

We claim:

1. A hydraulic power transmitter of the kinetic type comprising a working chamber including driving and driven vaned elements, a reservoir chamber arranged to rotate with said working chamber, a drain port which is incapable of being closed while said chambers are rotating, which communicates between said chambers and which is capable of exhausting working liquid, under the influence of its energy of motion, from said working chamber, a scoop which is disposed in said reservoir chamber and which is capable of angular displacement eccentrically with respect to the axis of rotation of the transmitter, a filling duct leading from said scoop to said working chamber, and control means for displacing said scoop which is so arranged that, in moving towards the position yielding-the maximum degree of filling of said working chamber, its scooping lip moves oppositely to the normal direction of rotation of said chambers.

v 2. A hydraulic power transmitter of the kinetic type comprising a working chamber including driving and driven varied elements, a reservoir chamber arranged to rotate with said working chamber, a drain port which is incapable of being closed while said chambers are rotating, which communicates between said chambers and which is capable of exhausting working liquid, under the influence of its energy of motion, from said working chamber, a scoop which is disposed in said reservoir chamber and which is capable of angular displacement eccentrically with respect to the axis of rotation of the transmitter, a filling duct leading from said scoop to said working chamber, biasing means capable of maintaining said scoop in the position yielding the maximum degree of filling of said working chamber, and an actuating member operable for displacing said scoop in such a sense that its scooping lip moves in the direction of rotation of said chambers towards the position yielding the minimum degree of filling of said working chamber.

3. A hydraulic power transmitter of the kinetic type comprising a working chamber formed by an impeller element and a dished shell fixed thereto and enclosing the back of a runner element, a reservoir chamber arranged to rotate with said working chamber and disposed on the side of said shell remote from said impeller element, the back of said impeller element being exposed to the atmosphere, a drain port which is incapable of being closed while said chambers are rotating, which communicates between said chambers and which is capable of exhausting working liquid, under the influence of its energy of motion, from said working chamber, the radius of said reservoir chamber about the axis of rotation of the transmitter exceeding the radius on which said outlet port is disposed, a fixed sleeve passing through said reservoir chamber, a driven shaft fixed on said runner and housed in said sleeve, a scoop which is mounted on said sleeve in said reservoir chamber and which is capable of angular displacement eccentrically with respect to said axis, a filling duct leading from said scoop through said sleeve to said working chamber, and means for controlling the displacement of said scoop.

4. A hydraulic power transmitter of the kinetic type comprising a working chamber including driving and driven varied elements, a reservoir chamber arranged to rotate with said working chamber, a drain port which is incapable of being closed while said chambers are rotating, which communicates between said chambers and which is capable of exhausting working liquid, under the influence of its energy of motion, from said working chamber, a rapid-emptying valve communicating between said chambers and adapted to be kept closed by liquid under centrifugal force in a control duct, a filling duct leading to said working chamber, a scoop device which is disposed in said reservoir chamber, which is capable of angular displacement eccentrically with respect to the axis of rotation of the transmitter and which comprises a main scoop tube arranged to feed said filling duct and an auxiliary scoop tube arranged to feed control duct.

5. A hydraulic power transmitter of the kinetic type comprising an annular working chamber having internal vanes an end wall provided with a central aperture, a shaft penetrating said aperture, a vaned member disposed within said working chamber and fixed to said shaft, a hydraulically-controlled valve mounted on said working chamber, a circumferential channel formed on the outside of said end wall and opening towards the axis of rotation of the transmitter, a control duct leading from said channel to said valve, means for supplying control liquid to said channel, and a shield tube disposed between said shaft and said channel for preventing liquid that leaks out of said working chamber through said aperture from entering said channel. 1

6. A hydraulic power transmitter of the kinetic type comprising a working chamber formed by an impeller element and a dished shell fixed thereto and enclosing the back of a runner element, a

reservoir chamber arranged to rotate with said working chamber and disposed on the side of said shell remote from said impeller element, apassage between said chambers which is incapable of being closed while said chambers are rotating and which is so placed as to be capable of exhausting at least a part of the liquid content of said working chamber to said reservoir chamber, a fixed support projecting into said reservoir chamber, a scoop mounted on said support for engaging liquid in said reservoir chamber and provided with a by-pass nozzle positioned to direct a jet of liquid on the end wall of said reservoir chamber remote from said working chamber, and a filling duct leading from said scoop to said working chamber.

7. In a hydraulic power transmitter, a rotary reservoir chamber having an end wall provided with a central aperture, a support penetrating said aperture, a liquid-transfer scoop in said chamber and mounted on said support. and a gland for restraining leakage between said wall and said support, said gland comprising a tube fixed to the inner side of said well and surrounding said support, an annular diaphragm fixed within said tube intermediate its ends. and provided with a drain port through its outer marginal portion, and an annular disk fixed to said support and disposed within said tube on the side of said diaphragm remote from said wall, the surface of said support within the part of said tube between said wall and said diaphragm being shaped to prevent axial creeping of liquid therealong.

8. A hydraulic starting clutch comprising a. Working chamber having internal vanes, a. varied rotor accommodated within said working chamber, said vaned members constituting the driving and driven portions-of the clutch, a reservoir chamber mounted for rotation with said working chamber and having an efltective capacity of at least 50 per cent. of the capacity of said workingchamber, a permanently-open exhaust passage between said chambers positioned to allow working liquid to gravitate from said working chamber to said reservoir chamber when said clutch is at rest, and means for engaging said clutch automatically at a predetermined rate including a non-rotating support in said reservoir chamber, a scoop mounted on said support for engaging and so disposed that it invariably picks up liquid carried round in said reservoir chamber when said working chamber is partly emptied to said reserarenas? voir chamber, and a filling duct leading from said scoop to said working chamber.

9. A hydraulic power transmitter of the kinetic type comprising a working chamber including driving and driven vaned elements, a rotatable reservoir chamber co -axial with and surrounding at least a part of said working chamber, a

drain passage communicating between said chambers and capable, at least when said transmitter is operating with substantial slip, of continuously exhausting heated liquid, under the infiuence of its energy of motion, from said working chamber to said reservoir chamber, a scoop which is disposed in said reservoir chamber and which is capable of angular displacement eccer1- trically with respect to the axis of rotation of said transmitter, a filling duct which is separate from said drain passage and which leads from said scoop to said working chamber, and control means for displacing said scoop and for fixing it in positions which lie between the limits of its effective range of displacement andwhich maintain respectively diiferent degrees of filling of said working chamber.

10. A hydraulic power transmitter for use as a. starting clutch and comprising a working chamber provided with impelling vanes and enclosing a runner, a rotatable reservoir chamber juxtaposed to and surrounding at least a part of said working chamber, said chambers communicating with each other by means positioned to discharge at least a part of the liquid content of said working chamber to said reservoir chamber when said transmitter is at rest, and said reservoir chamber being capable, when it is rotating, of containing working liquid maintained in ring form by centrifugal force, a scoop which is disposed in" said reservoir chamber and which is capable of angular dis placement eccentrically with respect to the axis of rotation of said transmitter, a filling duct leading from said scoop to said working chamber, biasing means which urge said scoop to move from the outer position yielding the maximum to the inner position yielding the minimum degree of filling of said working chamber and at the same time oppositely to the direction of rotation of said chambers, and a stop so determining said inner position that the mouth of said scoop engages only the radially innermost layer of said ring 0! liquid, the strength of said biasing means being such that, when the speed of said chambers rises to a predetermined value, the force due to the scooping action automatically displaces said scoop to said outer position. I

11. A hydraulic power transmitter of the kinetic type comprising a. working chamber provided with impelling vanes and enclosing a vaned runner, a rotary reservoir chamber co-axial with and at least partly surrounding said working chamber, means for discharging liquid from said working chamber to said reservoir chamber, a non-rotatable sleeve passing through a central aperture in an end wall of said reservoir chamber, a driven shaft to which said runner is fixed and which is housed in said sleeve, a labyrinth gland for restraining leakage between said sleeve and the edge of said aperture, a scoop mounted on said sleeve within said reservoir chamber and capable of angular displacement eccentrlcally with respect to the axis of rotation of sald'transmltter, a. filling duct in said sleeve and leading from said scoop to said working chamber, and means for controlling the displacement of said scoop, said reservoir chamber being so dimensioned that the normal maximum liquid content or said working chamber can be accommodated within said transmitter below said aperture when said transmitter is at rest with its axis horizontal.

12. A hydrauliccoupling for use as a starting clutch and comprising a driving part which is capable of being connected ,to a driving motor and which includes a working chamber containing impelling vanes and a reservoir chamber juxtaposed to and constrained to rotate with said working chamber, said chambers communicating with each other by means positioned to discharge automatically at least per cent. of the normal maximum liquid content of said working chamher to said reservoir chamber when said chambers are at rest, a non-rotatable sleeve passing coaxially through a' central aperture in an end wall of said reservoir chamber, a runner disposed within said working chamber, a driven shaft to which said runner is fixed and which is housed in said sleeve, a labyrinth gland associated with said aperture for restraining leakage between said end wall and said sleeve, and a filling duct including a scoop mounted on said sleeve within said reservoir chamber for engaging liquid therein and a passage in said sleeve leading to said working chamber, said filling duct having a flow capacity so selected that, when the driving motor is started, said scoop delivers liquid to said working chamber at a limited rate such that the motor has time to accelerate to a suitable speed before the working chamber is full enough to transmit the full-load torque of the motor.

13. A hydraulic power transmitter of the kinetic type comprising a rotatable working chamber including driving and driven vaned elements, a rotatable reservoir chamber at least in part surrounding said working chamber, a hydraulicallycontrolled emptying valve disposed in the wall of said working chamber and opening into said reservoir chamber, liquid transfer means opening out of said reservoir chamber for leading control liquid to said .valve, a support passing axially through said reservoir chamber, a scoop on said support for engaging liquid in said reservoir chamber, said scoop having a main outlet leading to said working chamber and an auxiliary outlet capable of supplying liquid to said liquid transfer means for the purpose of controlling said valve, and control means operable for interrupting the flow through said scoop.

14. A hydraulic power transmitter of the kinetic type comprising a rotatable working chamber including driving and driven vaned elements, a

rotatable reservoir chamber at least in part surrounding said working chamber, a hydraulicallycontrolled emptying valve disposed on said working chamber for discharging liquid therefrom to said reservoir chamber, said valve being adapted to be kept closed by liquid under centrifugal force in a control duct rotatable with said working chamber and opening out of said reservoir chamber, a filling duct leading from said reservoir chamber to the interior of said working chamber, and a scoop device which is disposed in said reservoir chamber for engaging liquid therein, which is capable of angular displacement eccentrically with respect to the axis of rotation of said transmitter and which includes a main outlet leading to said filling duct and an auxiliary outlet capable of charging said control duct.

15. A hydraulic power transmitter of the kinetic type comprising a working chamber including driving and driven varied elements juxtaposed to form a working circuit having the form of a toroidal ring, a rotatable reservoir chamber at least partly surrounding said working chamber and having an internal diameter of between and per cent. of the outer profile diameter of said toroidal working circuit, said working chamber having an emptying passage leading to said reservoir chamber from substantially the radially outermost part of said working chamber,

a fixed sleeve projecting coaxially into said reset volr chamber through a central aperture in an end wall thereof, a labyrinth gland associated with said aperture for restraining leakage between said end wall and said sleeve, a shaft fixed to one of said vaned elements and housed in said sleeve, a scoop mounted on said sleeve for engaging liquid in said reservoir chamber, said scoop being capable of angular displacement eccentrically with respect to the axis of rotation of said transmitter, a filling duct leading from said scoop through said sleeve to said working chambar, and an actuating member for said scoop journalled within the part of said sleeve which extends through said aperture.

16. A hydraulic power transmitter oi the kinetic type comprising a rotatable working chamber having a central aperture in an end wall thereof 25 and an internally vaned, portion, a varied rotor which is accommodated within said working chamber and which is juxtaposed to said vaned portion to form therewith a toroidal working cir-v cuit, a rotatable reservoir shell which is co-axial N with and encloses at least a part of said working chamber, which has an effective capacity of at least 50 per cent. of the normal maximum liquid content of said working chamber, and which has a central aperture in an end wall thereof, a fixed sleeve penetrating said apertures, a labyrinth gland including a tubular projection. which extends from the end wall of said shell through the interior of the reservoir, said projection having an annular flange, said flange and the inner border of the associated end wall forming an annular channel opening radially inward and provided with a drain port in the neighborhood of its periphery, a. shaft accommodated within said sleeve and fixed to said rotor, a passage for exhausting liquid from said working chamber to said reservoir shell, a scoop carried by said sleeve within said reservoir shell and capable of angular displacement eccentrically with respect to said shaft, and a control member journalled within the part of said sleeve which extends within said second mentioned aperture and said gland and operatively connected vnth said scoop, said sleeve including a filling duct leading from said scoop to the interior of said working chamber.

17. A hydraulic power transmitter of the kinetic type comprising an annular working chamber having internal vanes and an end wall provided with a central aperture, a shaft penetrating said aperture, a vaned member disposed within said working chamber and fixed to said shaft, a hydraulically-controlled valve mounted on and capable of exhausting liquid from said working chamher, said valve being adapted to be kept closed by liquid under centrifugal force contained in a control duct rotating with said working chamber and having a mouth disposed on said end wall outside said working chamber, means for supplying control liquid to said mouth, and a shield member mounted on said working chamber and 70 1a. In combination, a driving shaft, a hydraulic 1s power transmitter of the kinetic type comprising a driving portion which is rigifily fixed to said shaft and which includes a rotary seeing having an end Wall remote from said shaft, a, runner accommodated Within said casing, a fixed support including a sleeve which penetrates a central aperture in said end wall which is p2o vided with a duct for filing said transmitfier, a driven shaft passing through seam sleeve and carrying said runner, and co-opemting rings for the register of alignment and axial relationship of said driving shaft and-said sleeve, said rings being mounted respectively on said fixed support and on the outside of said end well.

rings emirefing said runner shaft, ene being con necized to said driving shaft and the other mounted independently theeeof for checking the alignment of the driving driven, shafts.

EQBRULE SENCLAIR.

CECIL 

